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I am in need of a performance-oriented hash function implementation in C++ for a hash table that I will be coding. I looked around already and only found questions asking what's a good hash function "in general". I've considered CRC32 (but where to find good implementation?) and a few cryptography algorithms. My table, though, has very specific requirements.

Here's what the table will be like:

100,000 items max
200,000 capacity (so the load is 0.5)
hashing a 6-character string which is a part of English sentence
     examples: "become"    "and he"    ", not "

The number one priority of my hash table is quick search (retrieval). Quick insertion is not important, but it will come along with quick search. Deletion is not important, and re-hashing is not something I'll be looking into. To handle collisions, I'll be probably using separate chaining as described here. I have already looked at this article, but would like an opinion of those who have handled such task before.

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I also added a hash function you may like as another answer – Robert Gould Mar 10 '09 at 3:37
If you are desperate, why haven't you put a rep bounty on this? – jmucchiello Mar 10 '09 at 3:56
rep bounty: i'd put it if nobody was willing offer useful suggestions, but i am pleasantly surprised :) – DV. Mar 10 '09 at 4:00
Anyways an issue with bounties is you can't place bounties until 2 days have passed – Robert Gould Mar 10 '09 at 4:32
Have you considered using one or more of the following general purpose hash functions: they are extremely fast and efficient. – Matthieu N. Jan 23 '11 at 10:10

9 Answers 9

up vote 22 down vote accepted

Now assumming you want a hash, and want something blazing fast that would work in your case, because your strings are just 6 chars long you could use this magic:

size_t precision = 2; //change the precision with this
size_t hash(const char* str)
   return (*(size_t*)str)>> precision;

CRC is for slowpokes ;)

Explanation: This works by casting the contents of the string pointer to "look like" a size_t (int32 or int64 based on the optimal match for your hardware). So the contents of the string are interpreted as a raw number, no worries about characters anymore, and you then bit-shift this the precision needed (you tweak this number to the best performance, I've found 2 works well for hashing strings in set of a few thousands).

Also the really neat part is any decent compiler on modern hardware will hash a string like this in 1 assembly instruction, hard to beat that ;)

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Wow.. could you elaborate what "((size_t)str)>> precision" does? It seems to do some weird pointer cast magic that I can't comprehend. And, "precision" is the number of digits in resulting index? – DV. Mar 10 '09 at 4:05
Yes precision is the number of binary digits – Robert Gould Mar 10 '09 at 4:25
ZOMG ZOMG thanks!!! I'm implementing a hash table with this hash function and the binary tree that you've outlined in other answer. – DV. Mar 10 '09 at 4:30
Note that this won't work as written on 64-bit hardware, since the cast will end up using str[6] and str[7], which aren't part of the string. Also, on 32-bit hardware, you're only using the first four characters in the string, so you may get a lot of collisions. – David Norman Mar 10 '09 at 5:14
I don't see how this is a good algorithm. The hash output increases very linearly. There's no avalanche effect at all... – Unknown Apr 29 '09 at 3:09

This simple polynomial works surprisingly well. I got it from Paul Larson of Microsoft Research who studied a wide variety of hash functions and hash multipliers.

unsigned hash(const char* s)
    unsigned h = SALT;
    while (*s)
        h = h * 101 + (unsigned) *s++;
    return h;

SALT should be initialized to some randomly chosen value before the hashtable is created to defend against hash table attacks. If this isn't an issue for you, just use 0.

The size of the table is important too, to minimize collisions. Sounds like yours is fine.

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Good candidate, I'll try it to see if performance is good. – DV. Mar 10 '09 at 7:45
And if you can guarentee that your strings are always 6 chars long without exception then you could try unrolling the loop. – Jackson Mar 10 '09 at 9:30
(unsigned char*) should be (unsigned char) I assume. – sgraham Jul 7 '13 at 4:21
sgraham: I changed the cast to (unsigned) in the loop. – George V. Reilly May 13 '14 at 20:28

Boost.Functional/Hash might be of use to you. I've not tried it, so I can't vouch for its performance.

Boost also has a CRC library.

I would look a Boost.Unordered first (i.e. boost::unordered_map<>). It uses hash maps instead of binary trees for containers.

I believe some STL implementations have a hash_map<> container in the stdext namespace.

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Since you store english words, most of your characters will be letters and there won't be much variation in the most significant two bits of your data. Besides of that I would keep it very simple, just using XOR. After all you're not looking for cryptographic strength but just for a reasonably even distribution. Something along these lines:

size_t hash(const std::string &data) {
  size_t h(0);
  for (int i=0; i<data.length(); i++)
    h = (h << 6) ^ (h >> 26) ^ data[i];
  return h;

Besides of that, have you looked at std::tr1::hash as a hashing function and/or std::tr1::unordered_map as an implementation of a hash table? Using these would probably be save much work opposed to implementing your own classes.

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thanks for suggestions! could you elaborate what does "h = (h << 6) ^ (h >> 26) ^ data[i];" do? as far as using c++ libraries, i won't be able to since this is a class exercise... – DV. Mar 10 '09 at 4:03
The ^ is the C++ operator for XOR, << and >> are bit shifts left and right to "mix it up" a little... – sth Mar 10 '09 at 4:17

The size of your table will dictate what size hash you should use. You would like to minimize collisions of course. I'm not sure what you are specifying by max items and capacity (they seem like the same thing to me) In any case either of those numbers suggest that a 32 bit hash would be sufficient. You might get away with CRC16 (~65,000 possibilities) but you would probably have a lot of collisions to deal with. On the other hand, a collision may be quicker to deal with than than a CRC32 hash.

I would say, go with CRC32. You'll find no shortage of documentation and sample code. Since you have your maximums figured out and speed is a priority, go with an array of pointers. Use the hash to generate an index. On collision, increment index until you hit an empty bucket.. quick and simple.

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The number one priority of my hash table is quick search (retrieval).

Well then you are using the right data structure, as searching in a hash table is O(1)! :)

The CRC32 should do fine. The implementation isn't that complex, it's mainly based on XORs. Just make sure it uses a good polynomial.

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How about something simple:

// Initialize hash lookup so that it maps the characters
// in your string to integers between 0 and 31
int hashLookup[256];

// Hash function for six character strings.
int hash(const char *str)
    int ret = 0, mult = 1;
    for (const char *p = str; *p; *p++, mult *= 32) {
        assert(*p >= 0 && *p < 256);
        ret += mult * hashLookup[*p];

    return ret;

This assumes 32 bit ints. It uses 5 bits per character, so the hash value only has 30 bits in it. You could fix this, perhaps, by generating six bits for the first one or two characters. If you character set is small enough, you might not need more than 30 bits.

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If you need to search short strings and insertion is not an issue, maybe you could use a B-tree, or a 2-3 tree, you don't gain much by hashing in your case.

The way you would do this is by placing a letter in each node so you first check for the node "a", then you check "a"'s children for "p", and it's children for "p", and then "l" and then "e". In situations where you have "apple" and "apply" you need to seek to the last node, (since the only difference is in the last "e" and "y")

But but in most cases you'll be able to get the word after a just a few steps ("xylophone" => "x"->"ylophone"), so you can optimize like this. This can be faster than hashing

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Elaborate on how to make B-tree with 6-char string as a key? Thanks! – DV. Mar 10 '09 at 3:14
Ah thanks, that's brilliant :) – DV. Mar 10 '09 at 3:34
One more thing, how will it decide that after "x" the "ylophone" is the only child so it will retrieve it in two steps?? – DV. Mar 10 '09 at 3:43
E.g., my struct is { char* data; char link{'A', 'B', .., 'a', 'b', ' ', ..}; } and it will test root for whether (node->link['x'] != NULL) to get to the possible words starting with "x". – DV. Mar 10 '09 at 3:46
When you insert data you need to "sort" it in. Lookup about heaps and priority queues. – Robert Gould Mar 10 '09 at 3:59

I'd second George Reilly's answer (on Paul Larson's multiplicative hash). The function is simple and elegant. Check hash function comparisons -

I've also noted that the STL implementation (for default hash function) uses the same algorithm except with a multiplicative factor of 5 (instead of 101)

Ref: (or find hash_fun.h at /usr/include/c++ on your linux distribution)

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